Complex best r-term approximations almost always exist in finite dimensions

Abstract

We show that in finite-dimensional nonlinear approximations, the best r-term approximant of a function f almost always exists over C but that the same is not true over R, i.e., the infimum ∈ff1,…,fr ∈ Y f - f1 - … - fr is almost always attainable by complex-valued functions f1,…, fr in Y, a set of functions that have some desired structures. Our result extends to functions that possess special properties like symmetry or skew-symmetry under permutations of arguments. For the case where Y is the set of separable functions, the problem becomes that of best rank-r tensor approximations. We show that over C, any tensor almost always has a unique best rank-r approximation. This extends to other notions of tensor ranks such as symmetric rank and alternating rank, to best r-block-terms approximations, and to best approximations by tensor networks. When applied to sparse-plus-low-rank approximations, we obtain that for any given r and k, a general tensor has a unique best approximation by a sum of a rank-r tensor and a k-sparse tensor with a fixed sparsity pattern; this arises in, for example, estimation of covariance matrices of a Gaussian hidden variable model with k observed variables conditionally independent given r hidden variables. The existential (but not the uniqueness) part of our result also applies to best approximations by a sum of a rank-r tensor and a k-sparse tensor with no fixed sparsity pattern, as well as to tensor completion problems.